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Geo-forestry of Landslide-affected Areas in a Part of Central Himalaya

Published online by Cambridge University Press:  24 August 2009

A.K. Tiwari ,
J.S. Mehta ,
O.P. Goel  and
J.S. Singh
A.K. Tiwari
Affiliation:
Wildlife Institute of India, New Forest, Dehradun 248 006, India; currently Scientist, Regional Remote Sensing Service Centre, Indian Space Research Organization, Bangalore 560025, India
J.S. Mehta
Affiliation:
Geological Survey of India, South Karnataka Project, Main Block, Jayanagar, Bangalore 560 011, India
O.P. Goel
Affiliation:
DOE Project on Landslides Study in Kumaun Himalaya, Reader, Department of Geology, Kumaun University, Naini Tal 263 002, India
J.S. Singh
Affiliation:
Banaras Hindu University, Varanasi 221 005, India.
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Extract

Black-and-white aerial photographs were used to map the lithology, land-use/forest types, and landslide zones (namely old, active, or potential) in a part of Central Himalaya. The landslide and land-use/forest type maps were simultaneously studied, and the frequency distribution of the landslide zones in different land-uses and forest types was estimated. The correlation between the maps indicated the following: In old landslide-affected sites, agriculture was the predominant land-use, followed by Pinus roxburghii forest (≤ 40% crown cover), scrub vegetation, and wasteland (including grassland). The presence of other forests (e.g. forests dominated by climax species such as Shorea robusta at low elevations and Quercus spp. at higher elevations) indicates a high potentiality of recovery of the ecosystems involved, provided biotic (especially anthropic) factors are not too intensive.

The active and potential landslide zones were concentrated along geologically active planes, namely thrusts and faults, and/or in the vicinity of toe-erosion of hill-slopes. These two were dominated by P.roxburghii forest (≤ 40% crown cover). The broadleaf forests showed minimal signs of active and potential landslides, perhaps because of their multistratal character which is conducive to minimizing soil-loss compared with the mostly single-storeyed Chir Pine forest. It is, therefore, suggested that the sites should be maintained under a multistratal broadleaf canopy to conserve the soil. Where, however, the Chir Pine forest is already developed, appropriate silvicultural measures may be taken to increase its crown cover to more than 40%.

Type
Main Papers
Information
Environmental Conservation , Volume 13 , Issue 4 , Winter 1986 , pp. 299 - 309
Copyright
Copyright © Foundation for Environmental Conservation 1986

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